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International Journal of Next-Generation Engineering and Technology

Open Access Peer Review International
Open Access

Artificial Intelligence-Driven Predictive Risk Analytics and Automation in Construction Project Management: Integrating Machine Learning, Computer Vision, And Data Intelligence for Safer and More Efficient Infrastructure Development

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Simone Marquez-Rodriguez 1 ,
4 Department of Civil and Infrastructure Systems Engineering, University of Valencia, Spain

Abstract

The global construction industry is characterized by high levels of uncertainty, complex stakeholder interactions, and persistent challenges related to cost overruns, safety incidents, and schedule delays. Traditional construction management practices have relied heavily on historical experience, heuristic decision-making, and manual monitoring systems that often struggle to address the increasing complexity of modern infrastructure projects. The emergence of artificial intelligence (AI), predictive analytics, and advanced data-driven technologies has introduced transformative opportunities for improving construction project performance. This research investigates how machine learning, computer vision, and predictive analytics can be integrated into construction management systems to enhance risk prediction, project planning, safety monitoring, and decision-making processes. Drawing upon interdisciplinary literature from civil engineering, data science, and risk management studies, the research develops a comprehensive conceptual framework that demonstrates how AI-driven predictive analytics can reshape the governance and execution of construction projects.

The study synthesizes insights from research on deep learning applications for infrastructure inspection, natural language processing for risk detection, machine learning-based cost prediction models, and computer vision techniques for safety monitoring. These technologies are examined alongside traditional construction risk management frameworks to evaluate how predictive analytics can improve risk identification, forecasting accuracy, and operational decision-making. The analysis highlights how hybrid machine learning models, Bayesian simulation approaches, and neuro-fuzzy inference systems can be applied to estimate project duration, financial risks, and operational hazards in large-scale infrastructure initiatives. Furthermore, the research explores the role of automated sensing technologies, including wearable sensors and intelligent monitoring systems, in enhancing workplace safety and compliance.

The findings indicate that integrating artificial intelligence with predictive risk analytics significantly improves the ability of project managers to anticipate potential disruptions and implement proactive mitigation strategies. AI-based systems demonstrate superior performance in identifying latent safety hazards, predicting cost escalation patterns, and detecting structural defects within construction environments. However, the study also identifies several limitations associated with data quality, algorithmic transparency, and technological adoption barriers within the construction sector. The research concludes that successful implementation of AI-driven predictive systems requires not only technological innovation but also organizational transformation, regulatory adaptation, and interdisciplinary collaboration among engineers, data scientists, and policymakers. By bridging theoretical insights with practical considerations, this study contributes to the growing body of knowledge on intelligent infrastructure systems and offers a roadmap for the responsible integration of artificial intelligence into future construction management practices.

Keywords

Artificial intelligence in construction, predictive analytics, construction risk management, machine learning

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